Post-irradiation DNA synthesis inhibition and G2 phase delay in radiosensitive body cells from non-Hodgkin's lymphoma patients: an indication of cell cycle defects

In the present study, both post-irradiation DNA synthesis and G₁ phase accumulation were analyzed in lymphoblastoid cell lines (LCLs) and fibroblast cell strains derived from (Saudi) patients with non-Hodgkin's lymphoma (NHL), ataxia telangiectasia (AT), AT heterozygotes and normal subjects. A comparison of the percent DNA synthesis inhibition (assayed by ³H-thymidine uptake 30 min after irradiation), and a 24 h post-irradiation G₂ phase accumulation determined by flow cytometry placed the AT heterozygotes and the NHL patients in an intermediate position between the normal subjects (with maximum DNA synthesis inhibition and minimum G₂ phase accumulation) and the AT homozygotes (with minimum DNA synthesis inhibition and maximum G₂ accumulation). The similarity between AT heterozygotes and the NHL patients with respect to the two parameters studied after irradiation was statistically significant. The data indicating a moderate abnormality in the control of cell cycle progression after irradiation in the LCLs and fibroblasts from NHL patients may explain the enhanced cellular and chromosomal radiosensitivity in these patients reported by us earlier. In addition to demonstrating a link between cell cyle abnormality and radiosensitivity as a possible basis for cancer susceptibility, particularly in the NHL patients, the present studies emphasized the usefulness of the assay for 24 h post-irradiation G₂ phase accumulation developed by Lavin et al. (1992) in characterizing AT heterozygote-like cell cycle anomally in cancer patients irrespective of whether they carried the AT gene or any other affecting the cell cycle.     

Extent of excision repair before DNA synthesis determines the mutagenic but not the lethal effect of UV radiation

Excision repair-proficient diploid fibroblasts from normal persons (NF) and repair-deficient cells from a xeroderma pigmentosum patient (XP12BE, group A) were grown to confluence and allowed to enter the G₀ state. Autoradiography studies of cells released from G₀ after 72 h and replated at lower densities (3?9 × 10³ cells/cm²) in fresh medium containing 15% fetal bovine serum showed that semiconservative DNA synthesis (S phase) began ～24 h after the replating. To determine whether the time available for DNA excision repair between ultraviolet irradiation (254 nm) and the onset of DNA synthesis was critical in determining the cytotoxic and/or mutagenic effect of UV in human fibroblasts, we released cultures of NF or XP12BE cells from G₀, allowed them to reattach at lower densities, irradiated them in early G₁ (～18 h prior to the onset of S) or just prior to S phase, and assayed the frequency of mutations to 6-thioguanine resistance and the survival of colony-forming ability. The XP12BE cells, which are virtually incapable of excising UV-induced DNA lesions, showed approximately the same frequency of mutations and survival regardless of the time of UV irradiation. In NF cells, the slope of the dose response for mutations induced in cells irradiated just prior to S was about 7-fold steeper than that of cells irradiated 18 h earlier. However, the two sets of NF cells showed no significant difference in survival. Neither were there significant differences in the survival of NF cells released from G₀, plated at cloning densities and irradiated as soon as they had attached and flattened out (～20 h prior to S) or 4, 8, 12, 16, 20 or 24 h later. We conclude that the frequency of mutations induced by UV is dependent upon the number of unexcised lesions remaining at the time of semi-conservative DNA replication. However, the amount of time available for excision of potentially cytotoxic lesions is not determined primarily by the period between irradiation and the onset of S phase.     

Reactivation of UV and γ-inactivated herpes virus in BHK cells

The DNA-repair capabilities of baby hamster kidney (BHK) cells were investigated by comparing the reactivation of irradiated herpes simplex virus type I (HSV1) in BHK cells with its reactivation in mouse fibroblasts and in normal and repairdeficient human diploid fibroblasts. BHK cells were found to have an intermediate ability to reactive UV-irradiated HSV1 (the viral D_o was 14 J/m²) relative to normal human fibroblasts (viral D_o = 19 J/m²) and xeroderma pigmentosum (XP) group A cells (viral D_o = 4.5 J/m²). With mouse L929 cells as the host, the response of the UV-irradiated virus was biphasic with D_os of 4.6 and 30 J/m² for the low- and high-dose components respectively. In contrast to the response following UV radiation, γ-irradiated HSV1 was similarly reactivated by BHK and normal human cells (the D_os for the irradiated virus in BHK and CRl 1106 were 55 and 51 krad, respectively, whereas xeroderma pigmentosum cells were slightly less efficient in the repair of γ-irradiated virus (D_o = 45 krad). UV irradiation of BHK host cells 0–48 h prior to infection enhanced the reactivation of UV-irradiated HSV.     

Mismatch repair proteins recruited to ultraviolet light-damaged sites lead to degradation of licensing factor Cdt1 in the G1 phase

Cdt1 is rapidly degraded by CRL4^Cdt2 E3 ubiquitin ligase after UV (UV) irradiation. Previous reports revealed that the nucleotide excision repair (NER) pathway is responsible for the rapid Cdt1-proteolysis. Here, we show that mismatch repair (MMR) proteins are also involved in the degradation of Cdt1 after UV irradiation in the G1 phase. First, compared with the rapid (within ～15 min) degradation of Cdt1 in normal fibroblasts, Cdt1 remained stable for ～30 min in NER-deficient XP-A cells, but was degraded within ～60 min. The delayed degradation was also dependent on PCNA and CRL4^Cdt2. The MMR proteins Msh2 and Msh6 were recruited to the UV-damaged sites of XP-A cells in the G1 phase. Depletion of these factors with small interfering RNAs prevented Cdt1 degradation in XP-A cells. Similar to the findings in XP-A cells, depletion of XPA delayed Cdt1 degradation in normal fibroblasts and U2OS cells, and co-depletion of Msh6 further prevented Cdt1 degradation. Furthermore, depletion of Msh6 alone delayed Cdt1 degradation in both cell types. When Cdt1 degradation was attenuated by high Cdt1 expression, repair synthesis at the damaged sites was inhibited. Our findings demonstrate that UV irradiation induces multiple repair pathways that activate CRL4^Cdt2 to degrade its target proteins in the G1 phase of the cell cycle, leading to efficient repair of DNA damage.     

Ubiquitin-dependent proteasomal degradation of AMPK gamma subunit by Cereblon inhibits AMPK activity

Cereblon (CRBN), a substrate receptor for Cullin-ring E3 ubiquitin ligase (CRL), is a major target protein of immunomodulatory drugs. An earlier study demonstrated that CRBN directly interacts with the catalytic α subunit of AMP-activated protein kinase (AMPK), a master regulator of energy homeostasis, down-regulating the enzymatic activity of AMPK. However, it is not clear how CRBN modulates AMPK activity. To investigate the mechanism of CRBN-dependent AMPK inhibition, we measured protein levels of each AMPK subunit in brains, livers, lungs, hearts, spleens, skeletal muscles, testes, kidneys, and embryonic fibroblasts from wild-type and Crbn^−/− mice. Protein levels and stability of the regulatory AMPKγ subunit were increased in Crbn^−/− mice. Increased stability of AMPKγ in Crbn^−/− MEFs was dramatically reduced by exogenous expression of Crbn. In wild-type MEFs, the proteasomal inhibitor MG132 blocked degradation of AMPKγ. We also found that CRL4^CRBN directly ubiquitinated AMPKγ. Taken together, these findings suggest that CRL4^CRBN regulates AMPK through ubiquitin-dependent proteasomal degradation of AMPKγ.     

The mechanism of bilirubin-photosensitized DNA strand breakage in human cells exposed to phototherapy light

Exposure of normal human fibroblasts to visible light (420–490 nm) in the presence of exogenously added 1–100 μg/ml bilirubin enhanced the level of DNA strand breakage compared with cells irradiated in the absence of added bilirubin. Treatment of cells in the dark with an irradiated bilirubin solution also induced DNA strand breaks. However, strand breakage was not detected in cells treated with an irradiated bilirubin solution that had been incubated with catalase (H₂O₂: H₂O₂ oxidoreductase EC 1.11.1.6). Examination of irradiated bilirubin solutions demonstrated the presence of hydrogen peroxide although, apparently, not at concentrations sufficient to account for the level of DNA strand breakage detected. Hence, irradiation of bilirubin results in the generation of hydrogen peroxide and possibly other peroxides that can cause DNA damage.     

Excision repair by human fibroblasts of DNA damaged by r-7, t-8-dihydroxy-t-9,10-OXY-7,8,9,10-tetrahydrobenzo(a)pyrene

Benzo(a)pyrene diol-epoxide I (r-7,t-8,dihydroxy-t-9,10 oxy-7,8,9,10 tetrahydrobenzo(a)pyrene) was used to treat either human adenovirus 5 or cultures of human fibroblasts. The survival of diol-epoxide I treated adenovirus was greater when infecting fibroblasts from normal persons than when infecting fibroblasts from patients with xeroderma pigmentosum (XP). One diol-epoxide I molecule bound per viral genome correlated with one lethal hit as measured using XP fibroblasts.Normal fibroblasts blocked in semi-conservative DNA synthesis incorporated into their DNA more [³H]thymidine in response to diol-epoxide I treatment than did XP fibroblasts, and also excised more diol-epoxide I from their DNA. All of the effects described above were similar to those obtained when the inactivating agent was ultraviolet light rather than benzo(a)pyrene diol-epoxide I.     

CDK1-dependent Inhibition of the E3 Ubiquitin Ligase CRL4CDT2 Ensures Robust Transition from S Phase to Mitosis

Replication-coupled destruction of a cohort of cell cycle proteins ensures efficient and precise genome duplication. Three proteins destroyed during replication via the CRL4^CDT2 ubiquitin E3 ligase, CDT1, p21, and SET8 (PR-SET7), are also essential or important during mitosis, making their reaccumulation after S phase a critical cell cycle event. During early and mid-S phase and during DNA repair, proliferating cell nuclear antigen (PCNA) loading onto DNA (PCNA^DNA) triggers the interaction between CRL4^CDT2 and its substrates, resulting in their degradation. We have discovered that, beginning in late S phase, PCNA^DNA is no longer sufficient to trigger CRL4^CDT2-mediated degradation. A CDK1-dependent mechanism that blocks CRL4^CDT2 activity by interfering with CDT2 recruitment to chromatin actively protects CRL4^CDT2 substrates. We postulate that deliberate override of replication-coupled destruction allows anticipatory accumulation in late S phase. We further show that (as for CDT1) de novo SET8 reaccumulation is important for normal mitotic progression. In this manner, CDK1-dependent CRL4^CDT2 inactivation contributes to efficient transition from S phase to mitosis.     

Thymine DNA Glycosylase Is a CRL4Cdt2 Substrate

The E3 ubiquitin ligase CRL4^Cdt2 targets proteins for destruction in S phase and after DNA damage by coupling ubiquitylation to DNA-bound proliferating cell nuclear antigen (PCNA). Coupling to PCNA involves a PCNA-interacting peptide (PIP) degron motif in the substrate that recruits CRL4^Cdt2 while binding to PCNA. In vertebrates, CRL4^Cdt2 promotes degradation of proteins whose presence in S phase is deleterious, including Cdt1, Set8, and p21. Here, we show that CRL4^Cdt2 targets thymine DNA glycosylase (TDG), a base excision repair enzyme that is involved in DNA demethylation. TDG contains a conserved and nearly perfect match to the PIP degron consensus. TDG is ubiquitylated and destroyed in a PCNA-, Cdt2-, and PIP degron-dependent manner during DNA repair in Xenopus egg extract. The protein can also be destroyed during DNA replication in this system. During Xenopus development, TDG first accumulates during gastrulation, and its expression is down-regulated by CRL4^Cdt2. Our results expand the group of vertebrate CRL4^Cdt2 substrates to include a bona fide DNA repair enzyme.     

The interaction of alcohol radicals with human hemoglobin

Aqueous deoxyhemoglobin solutions (2 mg/ml) were gamma-irradiated by a⁶⁰Co source in the presence of methanol, ethanol, 1-butanol andt-butanol under N₂O or argon. The effects of the interaction of the particular alcohol radical species with hemoglobin were determined according to the detected spectral alterations in the visible range. The amounts of stable final products in the form of methemoglobin (MetHb) and the sum of hemichromes and cholehemichromes (Hemichr) were estimated in irradiated preparations. For preparations irradiated under N₂O, the radiation yield for MetHb formation was threefold lower in the presence of ethanol and 1-butanol [G(MetHb)=0.33] compared with preparations irradiated in the presence oft-butanol or without alcohol [G(MetHb)=1.00]. The yield of hemichromes and cholehemichromes in preparations irradiated under N2O increased in the order: ethanol (G=0.38), 1-butanol (G=0.52),t-butanol (G=0.59), and in the absence of alcohol (G=0.72). The high effectivity oft-butanol radicals for iron oxidation and Hb destruction is apparently due to their oxidative properties, compared with the other radicals. It was also shown that ethanol radicals reduce MetHb 10 times more effectively [G(Fe(II)) = 2.5] compared witht-butanol radicals [G(Fe(II)) = 0.24]. For samples irradiated under argon all the observed changes were similar, regardless of the presence of alcohols. This effect can be attributed to reconstruction reactions of Hb molecules in the presence of both oxidizing (OH ort-but·) and reducing agents (e _aq ^/– ). The following sequence of effectivities of water radiolysis products and secondary alcohol radicals for hemoglobin destruction has been identified: meth·, eth·1-but·e _aq ^/– t-but··OH.This work was supported by State Committee for Scientific Research (Poland), grant no. 44509203     

An electrochemical analysis of changes in properties of DNA caused by ionizing and ultraviolet radiations

Summary Electrooxidation and electroreduction of- and u.v.-irradiated DNA were studied by means of differential pulse voltammetry at the graphite electrode and differential pulse polarography at the dropping mercury electrode. Two separated voltammetric oxidation peaks G and A were used for monitoring conformational changes in guanine - cytosine (GC) and adenine - thymine (AT) pairs respectively in irradiated double-stranded (ds) DNA. Pulse-polarography reduction peak III was used for detection of denatured DNA in the irradiated samples of ds DNA. It was found that the heights of peaks G and A of ds DNA did not change with the radiation dose after relatively low doses of- and u.v.-radiations (up to ca. 40 krads and 1 × 10⁴ Jm^–2, respectively), when no single-stranded (ss) DNA was detected in the irradiated DNA samples. After higher doses of radiation the occurrence of ss DNA or ss segments in the irradiated samples of ds DNA was accompanied by an increase of peaks G and A; however, peak A grew more rapidly with the increasing dose than peak G. It was concluded that the results obtained support the assumption, according to which regions of ds DNA rich in AT pairs are more susceptible to denaturation caused by- and u.v.-radiations.This dose concerns the DNA solution at a concentration of 600 µg/ml^–1     

Chromosomal radiosensitivity of ataxia telangiectasia cells at different cell cycle stages

Summary X-ray induced chromosomal aberrations in peripheral blood lymphocytes as well as in skin fibroblasts from ataxia telangiectasia patients, and from normal individuals were studied. At all stages of cell cycles—namely G₀, G₁, and G₂, more aberrations were induced in AT cells than in normal cells. In addition, AT cells were sensitive to induction of chromosomal aberrations by tritium beta rays from incorporated radioactive thymidine. Possible reasons for the increased sensitivity of AT cells for induction of chromosomal aberrations by ionizing radiations are discussed.     

Reciprocal induction of cell division by cells of complementary mating types in Tetrahymena

Chick embryo fibroblasts in monolayer culture were synchronized by contact inhibition and serum starvation. Nuclear DNA isolated from the [³H] thymidine pulse-labelled cells throughout the period of DNA synthesis (S phase) was analysed by hydroxylapatite chromatography after renaturation at different C₀t values. It is shown that repeated sequences having different frequencies of reassociation, replicate differently throughout the S period. In order to study the distribution of the repeated sequences, DNA isolated during the S period was fractionated according to its buoyant density. It is shown that only some of the highly reiterated sequences which are included in the high buoyant density DNA fractions, replicate equally well during the early and the late S periods. By contrast, reiterated sequences of the low buoyant density DNA fractions replicate mainly during the late S period.     

δβ-Thalassemia is due to a gene deletion

DNA has been prepared from peripheral blood or cultured skin fibroblasts obtained from three Sicilian and one Greek δβ-thalassemia homozygotes. Globin-gene analysis was carried out using a cDNA_β probe, and the results indicate that δβ-thalassemia has arisen from a deletion of the β-globin genes. A similar result was obtained using DNA prepared from cultured skin fibroblasts from an individual homozygous for the Negro form of hereditary persistence of fetal hemoglobin (HPFH). In both cases, the deletion has spared the ^Gγ and ^Aγ loci directing the γ chains of hemoglobin F, but it has not been possible to demonstrate any difference between the size of the deletion involved in the production of δβ-thalassemia and that which gave rise to HPFH. These experiments provide further direct evidence that deletions of critical areas of the γ-δ-β gene cluster result in persistent γ chain synthesis in adult life.     

A Novel Function of CRL4Cdt2: REGULATION OF THE SUBUNIT STRUCTURE OF DNA POLYMERASE δ IN RESPONSE TO DNA DAMAGE AND DURING THE S PHASE*

DNA polymerase δ (Pol δ4) is a heterotetrameric enzyme, whose p12 subunit is degraded in response to DNA damage, leaving behind a trimer (Pol δ3) with altered enzymatic characteristics that participate in gap filling during DNA repair. We demonstrate that CRL4^Cdt2, a key regulator of cell cycle progression that targets replication licensing factors, also targets the p12 subunit of Pol δ4 in response to DNA damage and on entry into S phase. Evidence for the involvement of CRL4^Cdt2 included demonstration that p12 possesses a proliferating cell nuclear antigen-interacting protein-degron (PIP-degron) and that knockdown of the components of the CRL4^Cdt2 complex inhibited the degradation of p12 in response to DNA damage. Analysis of p12 levels in synchronized cell populations showed that p12 is partially degraded in S phase and that this is affected by knockdowns of CUL4A or CUL4B. Laser scanning cytometry of overexpressed wild type p12 and a mutant resistant to degradation showed that the reduction in p12 levels during S phase was prevented by mutation of p12. Thus, CRL4^Cdt2 also regulates the subunit composition of Pol δ during the cell cycle. These studies reveal a novel function of CRL4^Cdt2, i.e. the direct regulation of DNA polymerase δ, adding to its known functions in the regulation of the licensing of replication origins and expanding the scope of its overall control of DNA replication. The formation of Pol δ3 in S phase as a normal aspect of cell cycle progression leads to the novel implications that it is involved in DNA replication as well as DNA repair.     

Characterisation of DNA from condensed and dispersed human chromatin

Condensed and dispersed chromatin fractions were isolated from human placental nuclei. The DNA of each fraction was purified and characterised by isopycnic centrifugation, thermal fractionation on hydroxylapatite (HAP) and sequence complexity studies. The DNAs had identical buoyant densities in neutral CsCl (1.698 g/cm³) and similar melting profiles on HAP. Analytical ultracentrifugation in Ag⁺-Cs₂SO₄, however, showed that satellite DNAs were present in the condensed fraction DNA (DNA_C) but were not visible in the dispersed fraction DNA (DNA_D). In addition, DNA_C was found to be enriched in highly reiterated sequences (20% reassociated by C₀t 10^?3) which can be correlated with the presence of satellite DNAs, whereas DNA_D contained only 3% of these fast reassociating sequences. In contrast DNA_D contained 30% intermediate sequences (reassociating between C₀t 10^?3 and C₀t 100) which represent only 10% of DNA_C. The reassociated highly repeated sequences of DNA_C showed the presence of two components in both CsCl density gradients and HAP thermal elution studies. This suggests that either there are sequence relationships resulting in partial mismatching between the different highly repeated DNA sequences in this fraction, or that highly repeated sequences are associated with less repetitious DNA. The results are discussed in terms of possible differences in genetic activity between the chromatin fractions.     

Effects of X-irradiation on cell-cycle progression, induction of chromosomal aberrations and cell killing in ataxia telangiectasia (AT) fibroblasts

Survival, cumulative labeling indices, chromosomal aberrations and cell-cycle distribution by flow microfluorometry (FMF) were studied in fibroblasts from normal and three ataxia telangiectasia (AT) families after X-irradiation during density-inhibition of growth and immediate release by subculture to low density. Homozygotic AT (proband) fibroblasts were very hypersensitive to cell killing by X-irradiation (D0 = 40-45 rad). Fibroblasts from AT heterozygotes (parents) were minimally hypersensitive, with D0's (100-110 rad) slightly lower than those for normal fibroblasts (D0 = 120-140 rad). There were three different response groups for a G1 phase block induced by 400 rad of X-rays: (1) minimal or no G1 block was observed in AT homozygote cell strains; (2) 10-20% of the cells were blocked in G1 in normal cell strains; and (3) 50% or more of the cells were blocked in AT heterozygote strains. FMF profiles and cumulative labeling indices showed that homozygotic AT cells irradiated in plateau phase moved into the S-phase following subculture with no additional delay over non-irradiated controls. Homozygotic AT cells showed not only a 4-5 times higher frequency of X-ray-induced chromosomal aberrations than normal strains, but approximately 30% of these were of the chromatid-type. There were no differences in the frequency or type of X-ray-induced chromosomal aberrations between normal and heterozygotic AT cells.